EP3737052A1 - Procédé et dispositif d'estimation de canal - Google Patents

Procédé et dispositif d'estimation de canal Download PDF

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Publication number
EP3737052A1
EP3737052A1 EP19743932.6A EP19743932A EP3737052A1 EP 3737052 A1 EP3737052 A1 EP 3737052A1 EP 19743932 A EP19743932 A EP 19743932A EP 3737052 A1 EP3737052 A1 EP 3737052A1
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EP
European Patent Office
Prior art keywords
space
frequency
vector
matrix
domain
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Pending
Application number
EP19743932.6A
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German (de)
English (en)
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EP3737052A4 (fr
Inventor
Xiaohan Wang
Huangping JIN
Xiang Ren
Wei Han
Xiaoyan Bi
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Huawei Technologies Co Ltd
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Huawei Technologies Co Ltd
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Application filed by Huawei Technologies Co Ltd filed Critical Huawei Technologies Co Ltd
Publication of EP3737052A1 publication Critical patent/EP3737052A1/fr
Publication of EP3737052A4 publication Critical patent/EP3737052A4/fr
Pending legal-status Critical Current

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    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04BTRANSMISSION
    • H04B7/00Radio transmission systems, i.e. using radiation field
    • H04B7/02Diversity systems; Multi-antenna system, i.e. transmission or reception using multiple antennas
    • H04B7/04Diversity systems; Multi-antenna system, i.e. transmission or reception using multiple antennas using two or more spaced independent antennas
    • H04B7/0413MIMO systems
    • H04B7/0456Selection of precoding matrices or codebooks, e.g. using matrices antenna weighting
    • H04B7/0478Special codebook structures directed to feedback optimisation
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04LTRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
    • H04L25/00Baseband systems
    • H04L25/02Details ; arrangements for supplying electrical power along data transmission lines
    • H04L25/0202Channel estimation
    • H04L25/024Channel estimation channel estimation algorithms
    • H04L25/0242Channel estimation channel estimation algorithms using matrix methods
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04BTRANSMISSION
    • H04B7/00Radio transmission systems, i.e. using radiation field
    • H04B7/02Diversity systems; Multi-antenna system, i.e. transmission or reception using multiple antennas
    • H04B7/04Diversity systems; Multi-antenna system, i.e. transmission or reception using multiple antennas using two or more spaced independent antennas
    • H04B7/0413MIMO systems
    • H04B7/0456Selection of precoding matrices or codebooks, e.g. using matrices antenna weighting
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04LTRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
    • H04L25/00Baseband systems
    • H04L25/02Details ; arrangements for supplying electrical power along data transmission lines
    • H04L25/0202Channel estimation
    • H04L25/0204Channel estimation of multiple channels
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04BTRANSMISSION
    • H04B7/00Radio transmission systems, i.e. using radiation field
    • H04B7/02Diversity systems; Multi-antenna system, i.e. transmission or reception using multiple antennas
    • H04B7/04Diversity systems; Multi-antenna system, i.e. transmission or reception using multiple antennas using two or more spaced independent antennas
    • H04B7/0413MIMO systems
    • H04B7/0417Feedback systems
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04LTRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
    • H04L25/00Baseband systems
    • H04L25/02Details ; arrangements for supplying electrical power along data transmission lines
    • H04L25/0202Channel estimation
    • H04L25/024Channel estimation channel estimation algorithms
    • H04L25/0242Channel estimation channel estimation algorithms using matrix methods
    • H04L25/0246Channel estimation channel estimation algorithms using matrix methods with factorisation

Definitions

  • This application relates to precoding technologies, and in particular, to a channel estimation method and apparatus.
  • the MIMO technology can significantly improve performance of a wireless communications system with a deployment of a plurality of antennas on a transmit end device and a receive end device. For example, in a diversity scenario, the MIMO technology can effectively improve transmission reliability, and in a multiplexing scenario, the MIMO technology can greatly improve a transmission throughput.
  • a precoding technology is usually used to make an improvement to a channel, to enhance a spatial multiplexing (spatial multiplexing) effect.
  • a precoding matrix matching the channel is used to process data flows to be spatially-multiplexed (briefly referred to as a spatial flow below), to perform precoding to the channel and improve receiving quality of the spatial flow.
  • Each spatially-multiplexed spatial flow corresponds to one column vector of the precoding matrix.
  • the transmit end device precodes the spatial flow by using the column vector. Therefore, the column vector may also be referred to as a precoding vector.
  • the precoding vector may be determined by the receive end device based on a space-domain base vector set, and is indicated to the transmit end device.
  • the space-domain base vector set is a set of a series of space-domain base vectors, and each space-domain base vector corresponds to one beam direction of the transmit end device.
  • a space-domain base vector that most matches a channel or a weighted sum of a plurality of space-domain base vectors that most match a channel may be used as a precoding vector, or the precoding vector is adjusted (for example but not limited to reconstruction), and an adjusted precoding vector is used for precoding.
  • the precoding vector is adjusted (for example but not limited to reconstruction), and an adjusted precoding vector is used for precoding.
  • there may be a plurality of spatially-multiplexed spatial flows. Precoding vectors of these spatial flows correspond to column vectors of a precoding matrix.
  • the precoding vector is usually a precoding vector used to precode one spatial flow in one frequency band.
  • the receive end device usually needs to indicate, to the transmit end device, precoding vectors corresponding to a plurality of frequency bands, and a precoding vector corresponding to each frequency band is independently indicated, causing relatively high indication overheads.
  • Embodiments of this application provide a channel estimation method and apparatus, to help reduce indication overheads.
  • an embodiment of this application provides a channel estimation method.
  • the method may include: generating indication information, where the indication information is used to indicate M N-dimensional precoding vectors, each precoding vector is applied to one of M frequency bands, the M N-dimensional precoding vectors form an N ⁇ M or M ⁇ N space-frequency matrix, and the space-frequency matrix is generated by performing weighted combination on a plurality of space-frequency component matrices, where M ⁇ 1, N ⁇ 2, and both M and N are integers; and sending the indication information.
  • the M N-dimensional precoding vectors can form a space-frequency matrix and the space-frequency matrix is generated by performing weighted combination on a plurality of space-frequency component matrices, a condition can be created for reducing indication overheads of the precoding vector.
  • the M N-dimensional precoding vectors can be indicated by indicating the space-frequency matrix.
  • the space-frequency matrix may be indicated by indicating the plurality of space-frequency component matrices. Therefore, compared with a technical solution in the prior art in which a precoding vector corresponding to each frequency band is independently indicated, the technical solution provided in this embodiment of this application helps reduce indication overheads.
  • the M N-dimensional precoding vectors form an N ⁇ M or M ⁇ N space-frequency matrix, in other words, the M N-dimensional precoding vectors form an X ⁇ Y space-frequency matrix, where X and Y are one and the other of M and N.
  • an embodiment of this application provides a channel estimation method.
  • the method may include: receiving indication information, where the indication information is used to indicate M N-dimensional precoding vectors, each precoding vector is applied to one of M frequency bands, the M N-dimensional precoding vectors form an N ⁇ M or M ⁇ N space-frequency matrix, and the space-frequency matrix is generated by performing weighted combination on a plurality of space-frequency component matrices, where M ⁇ 1, N ⁇ 2, and both M and N are integers; and determining the M N-dimensional precoding vectors based on the indication information.
  • the space-frequency matrix is specifically a space-frequency matrix in a narrow sense described below.
  • each space-frequency component matrix is selected from a space-frequency component matrix set, or is generated by performing weighted combination on a plurality of space-frequency base matrices selected from a space-frequency base matrix set.
  • the indication information is specifically used to indicate: the plurality of space-frequency component matrices and a weight of each of the plurality of space-frequency component matrices.
  • the indication information is specifically used to indicate: a plurality of space-frequency base matrices corresponding to each of the plurality of space-frequency component matrices, and weight information.
  • the weight information includes weights of the plurality of space-frequency base matrices and a weight of the space-frequency component matrix.
  • the weight information includes weights obtained by separately multiplying weights of the plurality of space-frequency base matrices by a weight of the space-frequency component matrix. In this way, indication overheads can be reduced.
  • each of the plurality of space-frequency component matrices is constructed based on two vectors, where one of the two vectors is constructed based on an N-dimensional space-domain component vector, and the other one is constructed based on an M-dimensional frequency-domain component vector.
  • the space-frequency matrix is an N ⁇ M space-frequency matrix
  • each of the plurality of space-frequency component matrices is a product of an N-dimensional space-domain component vector and a conjugate transpose vector of an M-dimensional frequency-domain component vector.
  • each of the plurality of space-frequency component matrices is a product of an M-dimensional frequency-domain component vector and a conjugate transpose vector of an N-dimensional space-domain component vector.
  • this application is not limited thereto.
  • each space-domain component vector is selected from a space-domain component vector set, or is generated by performing weighted combination on a plurality of space-domain base vectors selected from a space-domain base vector set.
  • each frequency-domain component vector is selected from a frequency-domain component vector set, or is generated by performing weighted combination on a plurality of frequency-domain base vectors selected from a frequency-domain base vector set.
  • the indication information is specifically used to indicate: a space-domain component vector and a frequency-domain component vector corresponding to each of the plurality of space-frequency component matrices, and a weight of the space-frequency component matrix.
  • the indication information is specifically used to indicate: a space-domain component vector and a plurality of frequency-domain base vectors corresponding to each of the plurality of space-frequency component matrices, and weight information.
  • the weight information includes weights of the plurality of frequency-domain base vectors and a weight of the space-frequency component matrix.
  • the weight information includes weights obtained by separately multiplying weights of the plurality of frequency-domain base vectors by a weight of the space-frequency component matrix. In this way, indication overheads can be reduced.
  • the indication information is specifically used to indicate: a frequency-domain component vector and a plurality of space-domain base vectors corresponding to each of the plurality of space-frequency component matrices, and weight information.
  • the weight information includes weights of the plurality of space-domain base vectors and a weight of the space-frequency component matrix.
  • the weight information includes weights obtained by separately multiplying weights of the plurality of space-domain base vectors by a weight of the space-frequency component matrix. In this way, indication overheads can be reduced.
  • the indication information is specifically used to indicate: a plurality of space-domain base vectors and a plurality of frequency-domain base vectors corresponding to each of the plurality of space-frequency component matrices, and weight information.
  • the weight information includes weights of the plurality of space-domain base vectors, weights of the plurality of frequency-domain base vectors, and a weight of the space-frequency component matrix.
  • the weight information includes weights obtained by separately multiplying weights of the plurality of space-domain base vectors by a weight of the space-frequency component matrix, and weights of the plurality of frequency-domain base vectors. In this way, indication overheads can be reduced.
  • the weight information includes weights obtained by separately multiplying weights of the plurality of frequency-domain base vectors by a weight of the space-frequency component matrix, and weights of the plurality of space-domain base vectors. In this way, indication overheads can be reduced.
  • any one of the foregoing indication information includes at least one piece of sub-information, each of the at least one piece of sub-information is used to indicate at least one piece of information indicated by any indication information, and sending periods of at least two pieces of sub-information are different or sending periods of all pieces of sub-information are the same.
  • each space-domain component vector when each space-domain component vector is generated by performing weighted combination on the plurality of space-domain base vectors, each of the plurality of space-frequency component matrices corresponds to a same group of space-domain base vectors. In this way, indication overheads can be reduced.
  • each frequency-domain component vector when each frequency-domain component vector is generated by performing weighted combination on the plurality of frequency-domain base vectors, each of the plurality of space-frequency component matrices corresponds to a same group of frequency-domain base vectors. In this way, indication overheads can be reduced.
  • the frequency-domain base vector in the frequency-domain base vector set is a column vector of a DFT matrix, or a column vector of an SVD unitary matrix.
  • the DFT matrix may be one-dimensional DFT matrix, or an oversampled one-dimensional DFT matrix.
  • an embodiment of this application provides a channel estimation method.
  • the method may include: generating indication information, where the indication information is used to indicate M N-dimensional precoding vectors, each precoding vector is applied to one of M frequency bands, the M N-dimensional precoding vectors form an M ⁇ N-dimensional space-frequency vector, and the space-frequency vector is generated by performing weighted combination on a plurality of space-frequency component vectors, where M ⁇ 1, N ⁇ 2, and both M and N are integers; and sending the indication information.
  • an embodiment of this application provides a channel estimation method.
  • the method may include: receiving indication information, where the indication information is used to indicate M N-dimensional precoding vectors, each precoding vector is applied to one of M frequency bands, the M N-dimensional precoding vectors form an M ⁇ N-dimensional space-frequency vector, and the space-frequency vector is generated by performing weighted combination on a plurality of space-frequency component vectors, where M ⁇ 1, N ⁇ 2, and both M and N are integers; and determining the M N-dimensional precoding vectors based on the indication information.
  • each space-frequency component vector is selected from a space-frequency component vector set, or is generated by performing weighted combination on a plurality of space-frequency base vectors selected from a space-frequency base vector set.
  • the indication information is specifically used to indicate: the plurality of space-frequency component vectors and a weight of each of the plurality of space-frequency component vectors.
  • the indication information is specifically used to indicate: a plurality of space-frequency base vectors corresponding to each of the plurality of space-frequency component vectors, and weight information.
  • the weight information includes: weights of the plurality of space-frequency base vectors and a weight of the space-frequency component vector.
  • the weight information includes weights obtained by separately multiplying weights of the plurality of space-frequency base vectors by a weight of the space-frequency component vector. In this way, indication overheads can be reduced.
  • a space-frequency component vector is constructed by using a Kronecker product of two vectors.
  • One of the two vectors is constructed based on an N-dimensional space-domain component vector, and the other one is constructed based on an M-dimensional frequency-domain component vector.
  • a space-frequency component vector is a Kronecker product of an N-dimensional space-domain component vector and an M-dimensional frequency-domain component vector.
  • a space-frequency component vector is a Kronecker product of an M-dimensional frequency-domain component vector and an N-dimensional space-domain component vector.
  • each space-domain component vector is selected from a space-domain component vector set, or is generated by performing weighted combination on a plurality of space-domain base vectors selected from a space-domain base vector set.
  • each frequency-domain component vector is selected from a frequency-domain component vector set, or is generated by performing weighted combination on a plurality of frequency-domain base vectors selected from a frequency-domain base vector set.
  • the indication information is specifically used to indicate: a space-domain component vector and a frequency-domain component vector corresponding to each of the plurality of space-frequency component vectors, and a weight of the space-frequency component vector.
  • the indication information is specifically used to indicate: a space-domain component vector and a plurality of frequency-domain base vectors corresponding to each of the plurality of space-frequency component vectors, and weight information.
  • the weight information includes weights of the plurality of frequency-domain base vectors and a weight of the space-frequency component vector.
  • the weight information includes weights obtained by separately multiplying weights of the plurality of frequency-domain base vectors by a weight of the space-frequency component vector. In this way, indication overheads can be reduced.
  • the indication information is specifically used to indicate: a frequency-domain component vector and a plurality of space-domain base vectors corresponding to each of the plurality of space-frequency component vectors, and weight information.
  • the weight information includes weights of the plurality of space-domain base vectors and a weight of the space-frequency component vector.
  • the weight information includes weights obtained by separately multiplying weights of the plurality of space-domain base vectors by a weight of the space-frequency component vector. In this way, indication overheads can be reduced.
  • the indication information is specifically used to indicate: a plurality of space-domain base vectors and a plurality of frequency-domain base vectors corresponding to each of the plurality of space-frequency component vectors, and weight information.
  • the weight information includes weights of the plurality of space-domain base vectors, weights of the plurality of frequency-domain base vectors, and a weight of the space-frequency component vector.
  • the weight information includes weights obtained by separately multiplying weights of the plurality of space-domain base vectors by a weight of the space-frequency component vector, and weights of the plurality of frequency-domain base vectors. In this way, indication overheads can be reduced.
  • the weight information includes weights obtained by separately multiplying weights of the plurality of frequency-domain base vectors by a weight of the space-frequency component vector, and weights of the plurality of space-domain base vectors. In this way, indication overheads can be reduced.
  • any one of the foregoing indication information includes at least one piece of sub-information, each of the at least one piece of sub-information is used to indicate at least one piece of information indicated by any indication information, and sending periods of at least two pieces of sub-information are different or sending periods of all pieces of sub-information are the same.
  • each space-domain component vector when each space-domain component vector is generated by performing weighted combination on the plurality of space-domain base vectors, each of the plurality of space-frequency component vectors corresponds to a same group of space-domain base vectors. In this way, indication overheads can be reduced.
  • each frequency-domain component vector when each frequency-domain component vector is generated by performing weighted combination on the plurality of frequency-domain base vectors, each of the plurality of space-frequency component vectors corresponds to a same group of frequency-domain base vectors. In this way, indication overheads can be reduced.
  • the frequency-domain base vector in the frequency-domain base vector set is a column vector of a DFT matrix, or a column vector of an SVD unitary matrix.
  • the DFT matrix may be one-dimensional DFT matrix, or an oversampled one-dimensional DFT matrix.
  • an embodiment of this application provides a channel estimation apparatus.
  • the channel estimation apparatus may be configured to perform any method according to the first aspect or the third aspect.
  • the channel estimation apparatus may be specifically a receive end device, for example, a network device or a terminal.
  • the channel estimation apparatus may be divided into functional modules according to the method provided in the first aspect or the third aspect.
  • the functional modules may be obtained through division corresponding to each function, or two or more functions may be integrated into one processing module.
  • the channel estimation apparatus may include a memory and a processor.
  • the memory is configured to store a computer program, and when the computer program is executed by the processor, any method provided in the first aspect or the third aspect is performed.
  • an embodiment of this application provides a channel estimation apparatus.
  • the channel estimation apparatus may be configured to perform any method according to the second aspect or the fourth aspect.
  • the channel estimation apparatus may be specifically a transmit end device, for example, a terminal or a network device.
  • the channel estimation apparatus may be divided into functional modules according to the method provided in the second aspect or the fourth aspect.
  • the functional modules may be obtained through division corresponding to each function, or two or more functions may be integrated into one processing module.
  • the channel estimation apparatus may include a memory and a processor.
  • the memory is configured to store a computer program, and when the computer program is executed by the processor, any method provided in the second aspect or the fourth aspect is performed.
  • the memory and the processor described in the embodiments of this application may be integrated into one chip, or may be separately disposed in different chips.
  • a type of the memory and disposing manners of the memory and the processor are not limited in the embodiments of this application.
  • an embodiment of this application provides a processor, where the processor may include: at least one circuit, configured to generate indication information, where the indication information is used to indicate M N-dimensional precoding vectors, and each precoding vector is applied to one of M frequency bands, the M N-dimensional precoding vectors form an N ⁇ M space-frequency matrix or an M ⁇ N space-frequency matrix, and the space-frequency matrix is generated by performing weighted combination on a plurality of space-frequency component matrices, or the M N-dimensional precoding vectors form an M ⁇ N-dimensional space-frequency vector, and the space-frequency vector is generated by performing weighted combination on a plurality of space-frequency component vectors, where M ⁇ 1, N ⁇ 2, and both M and N are integers.
  • the at least one circuit is configured to send the indication information by using a transmitter.
  • an embodiment of this application provides a processor, where the processor may include: at least one circuit, configured to receive indication information by using a receiver, where the indication information is used to indicate M N-dimensional precoding vectors, each precoding vector is applied to one of M frequency bands, the M N-dimensional precoding vectors form an N ⁇ M space-frequency matrix or an M ⁇ N space-frequency matrix, and the space-frequency matrix is generated by performing weighted combination on a plurality of space-frequency component matrices, or the M N-dimensional precoding vectors form an M ⁇ N-dimensional space-frequency vector, and the space-frequency vector is generated by performing weighted combination on a plurality of space-frequency component vectors, where M ⁇ 1, N ⁇ 2, and both M and N are integers.
  • the at least one circuit is configured to determine the M N-dimensional precoding vectors based on the indication information.
  • an embodiment of this application provides a processing device, including: a transmitter and a processor.
  • the processor is configured to: generate indication information, and send the indication information by using the transmitter.
  • the M N-dimensional precoding vectors form an N ⁇ M space-frequency matrix or an M ⁇ N space-frequency matrix, and the space-frequency matrix is generated by performing weighted combination on a plurality of space-frequency component matrices.
  • the M N-dimensional precoding vectors form an M ⁇ N-dimensional space-frequency vector, and the space-frequency vector is generated by performing weighted combination on a plurality of space-frequency component vectors.
  • M ⁇ 1, N ⁇ 2, and both M and N are integers.
  • an embodiment of this application provides a processing device, including a receiver and a processor.
  • the processor is configured to receive indication information by using the receiver, where the M N-dimensional precoding vectors form an N ⁇ M space-frequency matrix or an M ⁇ N space-frequency matrix, and the space-frequency matrix is generated by performing weighted combination on a plurality of space-frequency component matrices.
  • the M N-dimensional precoding vectors form an M ⁇ N-dimensional space-frequency vector, and the space-frequency vector is generated by performing weighted combination on a plurality of space-frequency component vectors.
  • M ⁇ 1, N ⁇ 2, and both M and N are integers.
  • the processor may be further configured to determine the M N-dimensional precoding vectors based on the indication information.
  • the processor may be configured to perform, for example but not limited to, baseband-related processing, and the receiver and the transmitter may be configured to perform, for example but not limited to, radio frequency sending and receiving.
  • the foregoing components may be separately disposed on chips independent of each other, or at least some or all of the components may be disposed on a same chip.
  • the receiver and the transmitter may be disposed on a receiver chip and a transmitter chip that are independent of each other, or may be integrated into a transceiver and then disposed on a transceiver chip.
  • the processor may be further classified into an analog baseband processor and a digital baseband processor.
  • the analog baseband processor and the transceiver may be integrated into a same chip, and the digital baseband processor may be disposed on an independent chip.
  • the digital baseband processor and a plurality of types of application processors may be integrated into a same chip.
  • Such a chip may be referred to as a system on chip (System on Chip). Whether all the components are separately disposed on different chips or integrated and disposed on one or more chips usually depends on a specific requirement of product design. A specific implementation of the components is not limited in the embodiments of this application.
  • An embodiment of this application further provides a computer-readable storage medium, where the computer-readable storage medium stores a computer program, and when the computer program is run on a computer, the computer is enabled to perform any one of the possible methods provided in the first aspect to the fourth aspect.
  • An embodiment of this application further provides a computer program product, where when the computer program product is run on a computer, any one of the methods provided in the first aspect to the fourth aspect is performed.
  • This application further provides a communications chip, where the communications chip stores an instruction, and when the instruction is run on a network device or a terminal, the network device or the terminal is enabled to perform the method according to any one of the first aspect to the fourth aspect.
  • any channel processing apparatus or processor or processing device or computer-readable storage medium or computer program product provided above is configured to perform a corresponding method provided above. Therefore, for beneficial effects that can be achieved by the channel processing apparatus or processor or processing device or computer-readable storage medium or computer program product, refer to the beneficial effects of the corresponding method, and details are not described herein.
  • the foregoing devices that are provided in the embodiments of this application and that are configured to store the computer instruction or the computer program, for example but not limited to, the foregoing memory, computer-readable storage medium, and communications chip, are all non-transitory (non-transitory).
  • the technical solutions provided in this application can be applied to various communications systems.
  • the technical solutions provided in this application may be applied to a 5G communications system, a future evolved system, a plurality of converged communications systems, or the like, or may be applied to an existing communications system or the like.
  • the technical solutions provided in this application may be applied to a plurality of application scenarios, such as machine to machine (machine to machine, M2M), macro-micro communication, enhanced mobile Internet (enhanced mobile broadband, eMBB), ultra-reliable low-latency communication (ultra reliable & low latency communication, URLLC), and massive machine-type communications (massive machine type communication, mMTC).
  • the scenarios may include but are not limited to a scenario of communication between terminals, a scenario of communication between network devices, a scenario of communication between a network device and a terminal, and the like.
  • the following describes the scenario used in communication between a network device and a terminal as an example.
  • FIG. 1 is a schematic diagram of a communications system to which the technical solutions provided in this application are applicable.
  • the communications system may include one or more network devices 100 (where only one network device is shown) and one or more terminals 200 connected to each network device 100.
  • FIG. 1 is only a schematic diagram, and does not constitute a limitation on an applicable scenario of the technical solutions provided in this application.
  • the network device 100 may be a transmission reception point (transmission reception point, TRP), a base station, a relay node, an access point, or the like.
  • the network device 100 may be a network device in a 5G communications system or a network device in a future evolved network, or may be a wearable device, a vehicle-mounted device, or the like.
  • the network device 100 may alternatively be a base transceiver station (base transceiver station, BTS) in a global system for mobile communications (global system for mobile communication, GSM) or code division multiple access (code division multiple access, CDMA) network, an NB (NodeB) in wideband code division multiple access (wideband code division multiple access, WCDMA), or an eNB or an eNodeB (evolutional NodeB) in a long term evolution (long term evolution, LTE).
  • the network device 100 may alternatively be a radio controller in a cloud radio access network (cloud radio access network, CRAN) scenario.
  • the terminal 200 may be user equipment (user equipment, UE), an access terminal, a UE unit, UE station, a mobile station, a remote station, a remote terminal, a mobile device, a UE terminal, a wireless communications device, a UE agent, a UE apparatus, or the like.
  • UE user equipment
  • the access terminal may be a cellular phone, a cordless phone, a session initiation protocol (session initiation protocol, SIP) phone, a wireless local loop (wireless local loop, WLL) station, a personal digital assistant (personal digital assistant, PDA), a handheld device having a wireless communication function, a computing device, another processing device connected to a wireless modem, a vehicle-mounted device, a wearable device, a terminal in a 5G network, a terminal in a future evolved public land mobile network (public land mobile network, PLMN) network, or the like.
  • SIP session initiation protocol
  • WLL wireless local loop
  • PDA personal digital assistant
  • the network elements for example, the network device 100 and the terminal 200 in FIG. 1 may be implemented by one device or may be jointly implemented by a plurality of devices, or may be implemented by a functional module in one device.
  • a functional module in one device.
  • the foregoing functions may be network elements in a hardware device, or may be software functions running on dedicated hardware, or may be virtualization functions instantiated on a platform (for example, a cloud platform).
  • each network element in FIG. 1 may be implemented by a communications device 400 in FIG. 2.
  • FIG. 2 is a schematic structural diagram of hardware of the communications device according to an embodiment of this application.
  • the communications device 400 includes at least one processor 401, a communications line 402, a memory 403, and at least one communications interface 404.
  • the processor 401 may be a general-purpose central processing unit (central processing unit, CPU), a microprocessor, an application-specific integrated circuit (application-specific integrated circuit, ASIC), or one or more integrated circuits configured to control program execution in the solutions of this application.
  • CPU central processing unit
  • ASIC application-specific integrated circuit
  • the communications line 402 may include a path for transmitting information between the foregoing components.
  • the communications interface 404 which uses any type of apparatus such as a transceiver, is configured to communicate with another device or a communications network, such as the Ethernet, a RAN, and a wireless local area network (wireless local area networks, WLAN).
  • a communications network such as the Ethernet, a RAN, and a wireless local area network (wireless local area networks, WLAN).
  • the memory 403 may be a read-only memory (read-only memory, ROM) or another type of static storage device capable of storing static information and instructions, a random access memory (random access memory, RAM) or another type of dynamic storage device capable of storing information and instructions, or may be an electrically erasable programmable read-only memory (electrically erasable programmable read-only memory, EEPROM), a compact disc read-only memory (compact disc read-only memory, CD-ROM) or another compact disc storage, an optical disc storage (including a compressed optical disc, a laser disc, an optical disc, a digital versatile disc, a Blu-ray optical disc, and the like), a magnetic disk storage medium or another magnetic storage device, or any other medium capable of carrying or storing expected program code in a form of instructions or data structures and capable of being accessed by a computer, but is not limited thereto.
  • ROM read-only memory
  • RAM random access memory
  • EEPROM electrically erasable programmable read-only memory
  • the memory may exist independently, and is connected to the processor by using the communications line 402. Alternatively, the memory may be integrated with the processor.
  • the memory provided in this embodiment of this application may be usually non-volatile.
  • the memory 403 is configured to store a computer executable instruction for performing the solutions in this application, and the processor 401 controls execution.
  • the processor 401 is configured to execute the computer executable instruction stored in the memory 403, to implement methods provided in the following embodiments of this application.
  • the computer executable instruction in this embodiment of this application may also be referred to as application program code. This is not specifically limited in this embodiment of this application.
  • the processor 401 may include one or more CPUs, for example, a CPU 0 and a CPU 1 in FIG. 2 .
  • the communications device 400 may include a plurality of processors, for example, the processor 401 and a processor 408 in FIG. 2 .
  • Each of the processors may be a single-core (single-CPU) processor, or may be a multi-core (multi-CPU) processor.
  • the processor herein may refer to one or more devices, circuits, and/or processing cores configured to process data (for example, a computer program instruction).
  • the communications device 400 may further include an output device 405 and an input device 406.
  • the output device 405 communicates with the processor 401, and may display information in a plurality of manners.
  • the output device 405 may be a liquid crystal display (liquid crystal display, LCD), a light emitting diode (light emitting diode, LED) display device, a cathode ray tube (cathode ray tube, CRT) display device, a projector (projector), or the like.
  • the input device 406 communicates with the processor 401, and may receive user input in a plurality of manners.
  • the input device 406 may be a mouse, a keyboard, a touchscreen device, a sensing device, or the like.
  • the communications device 400 may be a general-purpose device or a dedicated device.
  • the communications device 400 may be a desktop computer, a portable computer, a network server, a personal digital assistant (personal digital assistant, PDA), a mobile phone, a tablet computer, a wireless terminal device, an embedded device, or a device with a structure similar to that in FIG. 2 .
  • PDA personal digital assistant
  • a type of the communications device 400 is not limited in this embodiment of this application.
  • the receive end device may be the terminal 200 in FIG. 1
  • the transmit end device may be the network device 100 in FIG. 1
  • the receive end device may be the network device 100 in FIG. 1
  • the transmit end device may be the terminal 200 in FIG. 1 .
  • the following specific examples are all described by using an example in which the transmit end device is a network device and the receive end device is a terminal.
  • a system bandwidth may be divided into a plurality of frequency bands.
  • a quantity of frequency bands obtained by dividing the system bandwidth is not limited in this application, in other words, a frequency-domain granularity used during division into frequency bands is not limited.
  • the frequency-domain granularity may be one or more resource blocks (resource block, RB), or may be one or more subcarriers.
  • resource block resource block
  • subcarriers may be one or more subcarriers.
  • dividing the system bandwidth into a plurality of frequency bands refer to the prior art. For example, refer to a subband in the LTE standard to understand the frequency band.
  • Nre the quantity of frequency bands obtained by dividing the system bandwidth
  • Nsb a quantity of frequency bands corresponding to channel information that needs to be indicated and that is indicated by the transmit end device to the receive end device. 1 ⁇ Nsb ⁇ Nre, and both Nre and Nsb are integers.
  • the space-domain base vector set is a set of a series of space-domain base vectors.
  • the space-domain base vector set may be usually represented in a form of a matrix.
  • the space-domain base vector may be a column vector of the matrix.
  • Each space-domain base vector may correspond to one transmit beam (beam) of the transmit end device.
  • weighted combination may be performed on several space-domain base vectors in the space-domain base vector set to obtain a space-domain combined vector, and the space-domain combined vector may correspond to a new transmit beam.
  • the method for obtaining the new transmit beam through weighted combination may also be referred to as a beam combination technology.
  • the technology has been adopted in a new radio (new radio, NR) standard as a basic technology of a high-resolution precoding (namely, type II precoding) technology.
  • the space-domain base vector set may be, but is not limited to, a two-dimensional discrete Fourier transform (discrete fourier transform, DFT) matrix or an oversampled two-dimensional DFT matrix.
  • the space-domain base vector may be a column vector of the two-dimensional DFT matrix or a column vector of the oversampled two-dimensional DFT matrix.
  • the space-domain base vector may be a two-dimensional DFT vector.
  • the two-dimensional DFT vector may be usually used to describe a beam formed by superposing a beam in a horizontal direction and a beam in a vertical direction. Hence, this application is not limited thereto. Design manners of the space-domain base vector set have been described in detail in the prior art, and details are not described herein.
  • the space-domain base vector set may be predefined by both the receive end device and the transmit end device, for example, predefined according to a protocol. Especially, this application is not limited thereto.
  • vectors described in this specification may be understood as vectors of a same form, for example, a row vector or a column vector.
  • a quantity of dimensions of a space-domain base vector is the same as a quantity of dimensions of a precoding vector, and both are N.
  • both a space-domain base vector and a precoding vector include N elements.
  • N may be a quantity of transmit antenna ports of the transmit end device in one polarization direction, where N ⁇ 2, and N is an integer.
  • the frequency-domain base vector set is a set of a series of frequency-domain base vectors.
  • the frequency-domain base vector set may be usually represented in a form of a matrix.
  • the frequency-domain base vector may be a column vector of the matrix.
  • Each frequency-domain base vector may correspond to one frequency band variation pattern of a channel.
  • each frequency band may be represented by an element corresponding to the frequency band in a frequency-domain base vector.
  • elements corresponding to all frequency bands in the frequency-domain base vector can reflect one frequency band variation pattern.
  • weighted combination may be performed on several frequency-domain base vectors in the frequency-domain base vector set to obtain a frequency-domain combined vector, and the frequency-domain combined vector may correspond to a new frequency band variation pattern.
  • the frequency-domain combined vector refer to, for example but not limited to, the implementation principle of obtaining the space-domain combined vector by using the beam combination technology.
  • the frequency band variation pattern may be used to indicate a variation regularity of a channel in each frequency band in an entire frequency band including, for example, all frequency bands.
  • a frequency band variation pattern indicates a variation regularity of a channel in all frequency bands. For example, if elements of a frequency-domain base vector or a frequency-domain combined vector are equal, the frequency-domain base vector may indicate such a frequency band variation pattern that a channel remains unchanged in all frequency bands. For example, if adjacent elements of a frequency-domain base vector are greatly different from each other, the frequency-domain base vector may indicate such a frequency band variation pattern that a channel changes greatly in all frequency bands.
  • the frequency-domain base vector set may be, but is not limited to, one-dimensional DFT matrix, an oversampled one-dimensional DFT matrix, or a singular value decomposition (singular value decomposition, SVD) unitary matrix.
  • the frequency-domain base vector may be a column vector of the one-dimensional DFT matrix, a column vector of the oversampled one-dimensional DFT matrix, or a column vector of the SVD unitary matrix.
  • a principle of obtaining each frequency-domain base vector in the frequency-domain base vector set refer to a principle of obtaining each space-domain base vector in a space-domain base vector set in the prior art.
  • the frequency-domain base vector set is a one-dimensional DFT matrix.
  • a quantity of DFT points may be predefined or may be configured by the transmit end device for the receive end device, and the quantity of points may be a quantity of frequency bands. If the quantity of DFT points is configured by the transmit end device for the receive end device, the transmit end device may perform configuration in an explicit indication manner, or may perform configuration in an implicit indication manner. For example, if configuration is performed in the explicit indication manner, the transmit end device may perform configuration by using at least one of radio resource control (radio resource control, RRC) signaling, medium access control (medium access control, MAC) signaling, and downlink control information (downlink control information, DCI). For example, if configuration is performed in the implicit indication manner, specifically, the quantity of DFT points may be implicitly indicated by configuring Nre or Nsb.
  • RRC radio resource control
  • medium access control medium access control
  • DCI downlink control information
  • ⁇ A e -2 ⁇ i / A
  • i is an imaginary unit, 0 ⁇ j ⁇ A-1, and both j and A are integers.
  • A may be Nre or Nsb.
  • an expression form of the frequency-domain base vector may not be limited thereto.
  • the frequency-domain base vector set may be predefined by both the receive end device and the transmit end device, for example, predefined according to a protocol. Especially, this application is not limited thereto.
  • a quantity of dimensions of the frequency-domain base vector is M, in other words, the vector includes M elements.
  • M may be, for example, a quantity of frequency bands for which a precoding vector needs to be fed back, M ⁇ 1, and M is an integer.
  • the space-frequency base matrix set is a set of a series of space-frequency base matrices.
  • the space-frequency base matrix set may be represented in a form of a tensor. Hence, this application is not limited thereto.
  • Each element of the space-frequency base matrix set may be a space-frequency base matrix.
  • Each space-frequency base matrix may correspond to one transmit beam and one frequency band variation pattern of the transmit end device. Weighted combination may be performed on several space-frequency base matrices in the space-frequency base matrix set, to obtain a space-frequency combined matrix.
  • For an implementation principle of the space-frequency combined matrix refer to, for example but not limited to, the implementation principle of obtaining the space-domain combined vector by using the beam combination technology.
  • a space-frequency base matrix may be constructed based on two vectors, and one of the two vectors may be constructed based on a space-domain base vector and the other one may be constructed based on a frequency-domain base vector.
  • one of the two vectors may be one of a space-domain base vector and a frequency-domain base vector or a transformation thereof
  • the other one of the two vectors may be the other one of the space-domain base vector and the frequency-domain base vector or a transformation thereof.
  • the foregoing transformation may be, for example but not limited to, transpose, conjugate, conjugate transpose, and the like.
  • a space-frequency base matrix may be a product of a space-domain base vector and a conjugate transpose vector of a frequency-domain base vector; may be a product of a space-domain base vector and a transposed vector of a frequency-domain base vector; may be a product of a frequency-domain base vector and a conjugate transpose vector of a space-domain base vector; or may be a product of a frequency-domain base vector and a transposed vector of a space-domain base vector.
  • the two vectors for constructing the space-frequency base matrix may be set as a row vector and a column vector.
  • the space-frequency base matrix may be a product of the column vector and the row vector.
  • a space-frequency base matrix may be a product of a space-domain base vector and a conjugate transpose vector of a frequency-domain base vector, or a product of a frequency-domain base vector and a conjugate transpose vector of a space-domain base vector is used for description below.
  • a manner of constructing the space-frequency base matrix is not limited thereto, and the space-frequency base matrix may alternatively be constructed in another manner.
  • the space-frequency base matrix may be constructed by using a space-domain base vector and a frequency-domain base vector in, for example but not limited to, various manners described above or other manners.
  • the space-frequency base matrix set may be predefined by both the receive end device and the transmit end device, for example, predefined according to a protocol. Especially, this application is not limited thereto.
  • a quantity of dimensions of the space-frequency base matrix is N ⁇ M or M ⁇ N, in other words, the matrix includes N rows and M columns, or includes M rows and N columns.
  • the space-frequency base vector set is a set of a series of space-frequency base vectors.
  • the space-frequency base vector set may be usually represented in a form of a matrix.
  • the space-frequency base vector may be a column vector of the matrix.
  • Each space-frequency base vector may correspond to one transmit beam and one frequency band variation pattern of the transmit end device.
  • Weighted combination may be performed on several space-frequency base vectors in the space-frequency base vector set, to obtain a space-frequency combined vector.
  • For an implementation principle of the space-frequency combined vector refer to, for example but not limited to, the implementation principle of obtaining the space-domain combined vector by using the beam combination technology.
  • a space-frequency base vector may be a Kronecker product of two vectors.
  • One of the two vectors is constructed based on a space-domain base vector, and the other one is constructed based on a frequency-domain base vector.
  • one of the two vectors may be the space-domain base vector or a transformation thereof, and the other one of the two vectors may be the frequency-domain base vector or a transformation thereof.
  • the foregoing transformation may be, for example but not limited to, transpose, conjugate, conjugate transpose, and the like.
  • v is the space-frequency base vector.
  • u 1 is the space-domain base vector
  • u 2 is the frequency-domain base vector.
  • u 1 is a conjugate vector of u 1
  • u 2 is a conjugate vector of u 2 .
  • the two vectors for constructing the space-frequency base vector may both be set as row vectors or may both be set as column vectors.
  • the space-frequency base vector may be a Kronecker product of the two column vectors or a Kronecker product of the two row vectors.
  • a space-frequency base vector may be a Kronecker product of a space-domain base vector and a frequency-domain base vector, or a Kronecker product of a frequency-domain base vector and a space-domain base vector is used for description below.
  • a manner of constructing the space-frequency base vector is not limited thereto, and the space-frequency base vector may alternatively be constructed in another manner.
  • the space-frequency base vector may be constructed by using a space-domain base vector and a frequency-domain base vector in, for example but not limited to, various manners described above or other manners.
  • the space-frequency base vector set may be predefined by both the receive end device and the transmit end device, for example, predefined according to a protocol. Especially, this application is not limited thereto.
  • a quantity of dimensions of the space-frequency base vector is M ⁇ N, in other words, the vector includes M ⁇ N elements.
  • the space-domain component vector may be selected from the space-domain component vector set.
  • the space-domain component vector set is a set of a series of space-domain component vectors.
  • the space-domain component vector set may be usually represented in a form of a matrix.
  • the space-domain component vector may be a column vector of the matrix.
  • Each space-domain component vector may correspond to one transmit beam of the transmit end device.
  • the method for obtaining the space-domain component vector through selection may also be referred to as a beam selection technology.
  • the technology has been adopted in an NR standard as a basic technology of a low-resolution precoding (namely, type I precoding) technology.
  • the space-domain component vector set may be predefined by both the receive end device and the transmit end device, for example, predefined according to a protocol. Especially, this application is not limited thereto.
  • the space-domain component vector may be generated by performing weighted combination on a plurality of space-domain base vectors selected from a space-domain base vector set, in other words, the space-domain component vector is constructed based on a plurality of space-domain base vectors by using the beam combination technology.
  • the space-domain component vector is a space-domain combined vector.
  • a quantity of dimensions of the space-domain component vector is N, in other words, the vector includes N elements.
  • the frequency-domain component vector may be selected from the frequency-domain component vector set.
  • the frequency-domain component vector set is a set of a series of frequency-domain component vectors.
  • the frequency-domain component vector set may be usually represented in a form of a matrix.
  • the frequency-domain component vector may be a column vector of the matrix.
  • Each frequency-domain component vector may correspond to one frequency band variation pattern of the transmit end device.
  • an implementation principle of the method for obtaining the frequency-domain component vector in the selection manner refer to, for example but not limited to, the implementation principle of obtaining the space-domain component vector by using the beam selection technology.
  • the frequency-domain component vector set may be predefined by both the receive end device and the transmit end device, for example, predefined according to a protocol. Especially, this application is not limited thereto.
  • the frequency-domain component vector may be generated by performing weighted combination on a plurality of frequency-domain base vectors selected from the frequency-domain base vector set.
  • the frequency-domain component vector is a frequency-domain combined vector.
  • a quantity of dimensions of the frequency-domain component vector is M, in other words, the vector includes M elements.
  • the space-frequency component matrix may be selected from the space-frequency component matrix set.
  • the space-frequency component matrix set is a set of a series of space-frequency component matrices.
  • the space-frequency component matrix set may be represented in a form of a tensor. Hence, this application is not limited thereto.
  • Each element of the space-frequency component matrix set may be a space-frequency component matrix.
  • Each space-frequency component matrix may correspond to one transmit beam and one frequency band variation pattern of the transmit end device.
  • the method for obtaining the space-frequency component matrix in the selection manner refer to, for example but not limited to, the implementation principle of obtaining the space-domain component vector by using the beam selection technology.
  • the space-frequency component matrix may be generated by performing weighted combination on a plurality of space-frequency base matrices selected from the space-frequency base matrix set.
  • the space-frequency component matrix is a space-frequency combined matrix.
  • the space-frequency component matrix may be constructed based on two vectors, and the two vectors may be respectively constructed based on a space-domain component vector and a frequency-domain component vector.
  • one of the two vectors may be one of a space-domain component vector and a frequency-domain component vector or a transformation thereof
  • the other one of the two vectors may be the other one of the space-domain component vector and the frequency-domain component vector or a transformation thereof.
  • the foregoing transformation may be, for example but not limited to, transpose, conjugate, conjugate transpose, and the like.
  • the space-frequency component matrix may be a product of a space-domain component vector and a conjugate transpose vector of a frequency-domain component vector, a product of a space-domain component vector and a transposed vector of a frequency-domain component vector, a product of a frequency-domain component vector and a conjugate transpose vector of a space-domain component vector, or a product of a frequency-domain component vector and a transposed vector of a space-domain component vector.
  • the two vectors for constructing the space-frequency component matrix may be set as a row vector and a column vector.
  • the space-frequency component matrix may be a product of the column vector and the row vector.
  • the space-domain component matrix may be a product of a space-domain component vector and a conjugate transpose vector of a frequency-domain component vector, or a product of a frequency-domain component vector and a conjugate transpose vector of a space-domain component vector is used for description.
  • a manner of constructing the space-domain component matrix is not limited thereto, and the space-domain component matrix may alternatively be constructed in another manner.
  • the space-component matrix may be constructed by using a space-domain component vector and a frequency-domain component vector in, for example but not limited to, various manners described above or other manners.
  • a quantity of dimensions of the space-frequency component matrix is N ⁇ M or M ⁇ N, in other words, the matrix includes N rows and M columns, or includes M rows and N columns.
  • the space-frequency component vector may be selected from the space-frequency component vector set.
  • the space-frequency component vector set is a set of a series of space-frequency component vectors.
  • the space-frequency component vector set may be usually represented in a form of a matrix.
  • the space-frequency component vector may be a column vector of the matrix.
  • Each space-frequency component vector may correspond to one transmit beam and one frequency band variation pattern of the transmit end device.
  • an implementation principle of the method for obtaining the space-frequency component vector in the selection manner refer to, for example but not limited to, the implementation principle of obtaining the space-domain component vector by using the beam selection technology.
  • the space-frequency component vector may be generated by performing weighted combination on a plurality of space-frequency base vectors selected from the space-frequency base vector set.
  • the space-frequency component vector is a space-frequency combined vector.
  • the space-frequency component vector may be a Kronecker product of two vectors.
  • One of the two vectors is constructed based on a space-domain component vector
  • the other one of the two vectors is constructed based on a frequency-domain component vector.
  • one of the two vectors may be the space-domain component vector or a transformation thereof
  • the other one of the two vectors may be the frequency-domain component vector or a transformation thereof.
  • the foregoing transformation may be, for example but not limited to, transpose, conjugate, conjugate transpose, and the like.
  • transpose conjugate
  • conjugate transpose and the like.
  • a quantity of dimensions of the space-frequency component vector is M ⁇ N, in other words, the vector includes M ⁇ N elements.
  • the space-frequency matrix in a broad sense is a matrix formed by M precoding vectors. Each precoding vector is applied to one of M frequency bands, where the M frequency bands may be frequency bands for which channel information (for example but not limited to a precoding vector) needs to be fed back. M ⁇ 1, and M is an integer.
  • a precoding vector is usually used to represent channel information corresponding to a spatial flow in a frequency band.
  • a quantity of dimensions of the precoding vector is N, and N may be a quantity of transmit antenna ports of the transmit end device in a polarization direction. N ⁇ 2, and N is an integer.
  • the space-frequency matrix in a broad sense includes a space-frequency matrix in a narrow sense and a space-frequency vector.
  • the space-frequency matrix in a narrow sense is an N ⁇ M matrix (namely, a matrix of N rows and M columns) or an M ⁇ N matrix (namely, a matrix of M rows and N columns) formed by M precoding vectors.
  • N ⁇ M matrix namely, a matrix of N rows and M columns
  • M ⁇ N matrix namely, a matrix of M rows and N columns
  • the space-frequency vector is an M ⁇ N-dimensional vector (which includes M ⁇ N elements), that is, may be a space-frequency matrix in a broad sense whose column quantity is 1.
  • M ⁇ N-dimensional vector which includes M ⁇ N elements
  • the space-frequency matrix in a narrow sense may be represented in a form of a weighted combination of a plurality of space-frequency component matrices. It should be noted that, for ease of description, unless otherwise described, or unless otherwise obviously conflicting with a meaning to be expressed, the space-frequency matrix in the following description is the space-frequency matrix in a narrow sense. A unified description is provided herein and details are not described below again.
  • the space-frequency matrix may be obtained based on a channel matrix.
  • the channel matrix may be a matrix that is obtained by the receive end device based on a reference signal sent by the transmit end device and that is used to reflect channel information.
  • An implementation of obtaining the space-frequency matrix by the receive end device based on the channel matrix is not limited in this application. Several implementations are listed below: In an implementation, the receive end device may obtain an ideal space-frequency matrix H ' based on a channel matrix, and then approximately represent the ideal space-frequency matrix in a form of a weighted sum of a plurality of space-frequency component matrices.
  • W is a quantity of space-frequency component matrices.
  • h w is a w th space-frequency component matrix. 1 ⁇ w ⁇ W, W ⁇ 2, and both W and w are integers.
  • ⁇ w is a weight of h w .
  • the ideal space-frequency matrix H ' may be formed by M ideal precoding vectors.
  • each ideal precoding vector may be used as a column vector of the ideal space-frequency matrix H ' , or a conjugate transpose vector of each ideal precoding vector is used as a row vector of the ideal space-frequency matrix H ' .
  • Each ideal precoding vector corresponds to one of M frequency bands, where 1 ⁇ M ⁇ Nsb, and M is an integer.
  • the ideal precoding vector may be obtained by performing eigenvalue decomposition on a channel matrix or a related matrix of the channel matrix, and is used to represent channel information corresponding to a spatial flow in a frequency band.
  • the ideal space-frequency matrix may also be approximately expressed as a space-frequency component matrix.
  • the ideal space-frequency matrix H ' may be obtained in various manners. A specific manner is not limited in this embodiment of this application.
  • a precoding matrix in each of the M frequency bands may be arranged in a row direction or a column direction, to obtain an overall precoding matrix of the M frequency bands, and the precoding matrix is used as the ideal space-frequency matrix H ' .
  • a precoding matrix in each frequency band is an 8 ⁇ 2 matrix (whose rank (rank) is 2, that is, a quantity of transport layers is 2)
  • a precoding matrix in each of ten frequency bands may be arranged in a column direction, to obtain an 8 ⁇ 10 matrix (whose rank is 1, that is, a quantity of transport layers is 1).
  • a precoding matrix in each frequency band is an 8 ⁇ 2 matrix (whose rank is 2, that is, a quantity of transport layers is 2)
  • a precoding matrix in each of ten frequency bands may be arranged in a row direction, to obtain an 80 ⁇ 1 matrix (whose rank is 1, that is, a quantity of transport layers is 1).
  • determining the space-frequency component matrix and a weight thereof refer to content of determining beam components forming a precoding vector and weights thereof in a process for determining the precoding vector based on the beam combination technology. Related content can be found in the prior art, and details are not described in this specification.
  • each ideal precoding vector is used as a column vector of the ideal space-frequency matrix H '
  • the ideal space-frequency matrix H ' is an N ⁇ M matrix
  • the space-frequency matrix H is an N ⁇ M matrix
  • each space-frequency component matrix is an N ⁇ M matrix.
  • a conjugate transpose vector of each ideal precoding vector is used as a row vector of the ideal space-frequency matrix H '
  • the ideal space-frequency matrix H' is an M ⁇ N matrix
  • the space-frequency matrix H is an M ⁇ N matrix
  • each space-frequency component matrix is an M ⁇ N matrix.
  • the receive end device may preset a group of candidate weights, and the receive end device may traverse and combine each candidate space-frequency component matrix and each candidate weight, to obtain a plurality of combinations.
  • Each combination may include one or more candidate space-frequency component matrices and a candidate weight of each of the one or more candidate space-frequency component matrices.
  • weighted summation may be performed on several candidate space-frequency component matrices in the combination and a candidate weight of each of the candidate space-frequency component matrices, to obtain a candidate space-frequency matrix.
  • the candidate space-frequency matrix is an N ⁇ M matrix or an M ⁇ N matrix.
  • the candidate space-frequency component matrix may be obtained based on any manner of obtaining a space-frequency component matrix provided above.
  • a candidate space-frequency matrix corresponding to a candidate precoded channel matrix with a maximum channel capacity in the plurality of candidate precoded channel matrices is used as the space-frequency matrix H .
  • a w th candidate space-frequency component matrix in a combination corresponding to the space-frequency matrix H may be equivalent to h w
  • a candidate weight of the w th candidate space-frequency component matrix may be equivalent to ⁇ w .
  • a candidate space-frequency matrix is an N ⁇ M matrix
  • the obtaining, based on a plurality of candidate space-frequency matrices and channel matrices corresponding to M frequency bands, a plurality of candidate precoded channel matrices corresponding to the M frequency bands may include: using a product of a channel matrix corresponding to an m th frequency band in the M frequency bands and an m th column vector of the candidate space-frequency matrix as an m th column vector of the candidate precoded channel matrix, to obtain a candidate precoded channel matrix corresponding to the m th frequency band.
  • a candidate precoded channel matrix corresponding to the M frequency bands can be calculated.
  • a 4 ⁇ 8 channel matrix corresponding to the m th frequency band in the M frequency bands may be multiplied by the m th column vector (that is, an 8 ⁇ 1-dimensional vector) in the candidate space-frequency matrix, to obtain a 4 ⁇ 1-dimensional vector; and then, ten 4 ⁇ 1-dimensional vectors corresponding to ten frequency bands form a 4 ⁇ 10 matrix, and the matrix is a candidate precoded channel matrix corresponding to the ten frequency bands.
  • a candidate space-frequency matrix is an M ⁇ N matrix
  • the obtaining, based on a plurality of candidate space-frequency matrices and channel matrices corresponding to M frequency bands, a plurality of candidate precoded channel matrices corresponding to the M frequency bands may include: using a product of a channel matrix corresponding to an m th frequency band in the M frequency bands and an m th row vector of the candidate space-frequency matrix as an m th row vector of the candidate precoded channel matrix, to obtain a candidate precoded channel matrix corresponding to the m th frequency band.
  • a candidate precoded channel matrix corresponding to the M frequency bands can be calculated.
  • the foregoing example is an example of the implementation of obtaining the space-frequency matrix H based on the channel matrix, and does not constitute a limitation on obtaining the space-frequency matrix H based on the channel matrix.
  • the receive end device may indicate related information of the space-frequency matrix H to the transmit end device.
  • Each column of the space-frequency matrix H is a precoding vector, and to-be-sent data is precoded based on the M precoding vectors to send precoded data.
  • the space-frequency vector may be obtained based on a channel matrix.
  • An implementation of obtaining the space-frequency vector by the receive end device based on the channel matrix is not limited in this application. Several implementations are listed below:
  • the receive end device may obtain an ideal space-frequency vector V' based on the channel matrix, and then represent the ideal space-frequency vector in a form of a weighted sum of a plurality of space-frequency component vectors.
  • the weighted sum of the plurality of space-frequency component vectors is the space-frequency vector V , and therefore, it can be learned that the space-frequency vector V is an approximation of the ideal space-frequency vector V' .
  • Z is a quantity of space-frequency component vectors.
  • v z is a z th space-frequency component vector.
  • the ideal space-frequency vector V' may be formed by M ideal precoding vectors.
  • the ideal space-frequency vector may be an M ⁇ N-dimensional row vector (that is, the first row vector) arranged by expanding N ⁇ M ideal space-frequency matrix row by row; may be an M ⁇ N-dimensional column vector (that is, the first column vector) arranged by expanding N ⁇ M ideal space-frequency matrix column by column; may be an M ⁇ N-dimensional column vector (that is, the second column vector) arranged by expanding M ⁇ N ideal space-frequency matrix column by column; or may be an M ⁇ N-dimensional row vector (that is, the second row vector) arranged by expanding M ⁇ N ideal space-frequency matrix row by row.
  • a conjugate transpose vector of the first row vector is the second column vector.
  • a conjugate transpose vector of the second row vector is the first column vector.
  • the ideal space-frequency vector may also be approximately expressed as a space-frequency component vector.
  • the receive end device may preset a group of candidate weights, and the receive end device may traverse and combine each candidate space-frequency component vector and each candidate weight, to obtain a plurality of combinations.
  • Each combination may include one or more candidate space-frequency component vectors and a candidate weight of each of the one or more candidate space-frequency component vectors.
  • weighted summation may be performed on several candidate space-frequency component vectors in the combination and a candidate weight of each of the candidate space-frequency component vectors, to obtain a candidate space-frequency vector.
  • the candidate space-frequency vector is an M ⁇ N matrix.
  • the candidate space-frequency component vector may be obtained based on any manner of obtaining a space-frequency component vector provided above.
  • a candidate space-frequency vector corresponding to a candidate precoded channel matrix with a maximum channel capacity in the plurality of candidate precoded channel matrices is used as the space-frequency vector V .
  • a z th candidate space-frequency component vector in a combination corresponding to the space-frequency vector V may be equivalent to v z
  • a candidate weight of the z th candidate space-frequency component vector may be equivalent to ⁇ z .
  • a candidate precoded channel matrix corresponding to the M frequency bands may include: using a product of a channel matrix corresponding to an m th frequency band in the M frequency bands and an m th column vector of an N ⁇ M candidate space-frequency matrix corresponding to the candidate space-frequency vector as an m th column vector of the candidate precoded channel matrix, to obtain a candidate precoded channel matrix corresponding to the M frequency bands.
  • the candidate space-frequency vector is first converted into the N ⁇ M candidate space-frequency matrix, and then the channel matrix corresponding to the m th frequency band in the M frequency bands is multiplied by the m th column vector of the N ⁇ M candidate space-frequency matrix is not required.
  • the m th column vector may be directly captured from the candidate space-frequency vector, and then, the channel matrix corresponding to the m th frequency band in the M frequency bands is multiplied by the m th column vector.
  • a candidate precoded channel matrix corresponding to the M frequency bands may include: using a product of a channel matrix corresponding to an m th frequency band in the M frequency bands and an m th row vector of an M ⁇ N candidate space-frequency matrix corresponding to the candidate space-frequency vector as an m th row vector of the candidate precoded channel matrix, to obtain a candidate precoded channel matrix corresponding to the M frequency bands.
  • the foregoing example is an example of the implementation of obtaining the space-frequency vector V based on the channel matrix, and does not constitute a limitation on obtaining the space-frequency vector V based on the channel matrix.
  • the receive end device may indicate related information of the space-frequency vector V to the transmit end device.
  • a specific implementation of determining the M precoding vectors based on the space-frequency vector V may be understood as an inverse process of determining V .
  • the space-frequency component vector is a column vector. If the space-frequency vector is a row vector, the space-frequency component vector is a row vector.
  • the term "a plurality of” in this application means two or more than two.
  • the term “and/or” in this application describes only an association relationship for describing associated objects and represents that three relationships may exist.
  • a and/or B may represent the following three cases: Only A exists, both A and B exist, and only B exists.
  • the character "/" in this specification generally indicates an "or” relationship between the associated objects.
  • the character usually indicates a "division” relationship between the associated objects.
  • a formula A/B indicates that Ais divided by B.
  • the terms "first”, “second”, and so on are intended to distinguish between different objects but do not indicate a particular order of the obj ects.
  • any vector such as a space-domain base vector, a frequency-domain base vector, a space-domain component vector, a frequency-domain component vector, a space-frequency vector, a space-frequency base vector, or a precoding vector
  • a column vector is used for description below.
  • a unified description is provided herein, and details are not described below again.
  • any vector may alternatively be a row vector.
  • a person skilled in the art should be capable of properly inferring a corresponding technical solution when any vector is a row vector, based on the technical solution provided in this application without creative efforts. Details are not described in this specification.
  • forms of a vector and a matrix used in this specification may be adjusted based on a specific requirement.
  • a vector and a matrix are transposed, or a vector and/or a matrix is represented in a conjugate form of the vector and/or the matrix, a combination of the foregoing forms, another form, or the like. Therefore, the foregoing inferring and adjustment should be understood as falling within the scope of the embodiments of this application.
  • FIG. 3 is a schematic flowchart of a channel estimation method according to an embodiment of this application. The method shown in FIG. 3 may include the following steps.
  • a receive end device generates indication information, where the indication information is used to indicate M N-dimensional precoding vectors, each precoding vector is applied to one of M frequency bands, and the M N-dimensional precoding vectors form an N ⁇ M space-frequency matrix or an M ⁇ N space-frequency matrix.
  • the space-frequency matrix is generated by performing weighted combination on a plurality of space-frequency component matrices, where M ⁇ 1, N ⁇ 2, and both M and N are integers.
  • the M N-dimensional precoding vectors may be precoding vectors based on which a single spatial flow is sent in each of the M frequency bands.
  • M may be less than or equal to a quantity Nsb of frequency bands corresponding to channel information that is fed back by the receive end device, as instructed by a transmit end device.
  • one or more space-frequency matrices may be designed based on an actual requirement, provided that a sum of column vectors of the one or more space-frequency matrices is equal to Nsb.
  • precoding vectors corresponding to several continuous frequency bands may form a space-frequency matrix.
  • precoding vectors corresponding to the frequency bands 1, 2, and 3 may form an N ⁇ 3 or a 3 ⁇ N space-frequency matrix
  • precoding vectors corresponding to the frequency bands 8 and 9 may form an N ⁇ 2 or a 2 ⁇ N space-frequency matrix.
  • precoding vectors corresponding to the frequency bands 1, 2, 3, 8, and 9 may alternatively form an N ⁇ 5 or a 5 ⁇ N space-frequency matrix.
  • W is a quantity of space-frequency component matrices.
  • h w is a w th space-frequency component matrix.
  • ⁇ w is a weight of h w .
  • S102 The receive end device sends the indication information.
  • Information indicated by the indication information is referred to as to-be-indicated information.
  • the manners are, for example but not limited to, directly indicating the to-be-indicated information, for example, indicating the to-be-indicated information or an index of the to-be-indicated information.
  • the to-be-indicated information may be indirectly indicated by indicating other information, and there is an association relationship between the other information and the to-be-indicated information.
  • only a part of the to-be-indicated information may be indicated, and the other part of the to-be-indicated information is known or agreed on in advance.
  • specific information may be alternatively indicated based on an arrangement sequence of pieces of information agreed on in advance (for example, stipulated in a protocol), to reduce indication overheads to some extent.
  • a universal part of the pieces of information may be identified and indicated in a unified manner, to reduce indication overheads caused by separately indicating same information. For example, when six space-frequency component vectors are indicated, if the six space-frequency component vectors are results obtained by traversing three space-domain component vectors and two frequency-domain component vectors and calculating Kronecker products of the three space-domain component vectors and the two frequency-domain component vectors, there is no need to indicate a space-domain component vector and a frequency-domain component vector of each space-frequency component vector.
  • the three space-domain component vectors and the two frequency-domain component vectors are indicated in a unified manner, and the six space-frequency component vectors are jointly indicated with reference to another manner, to reduce indication overheads.
  • a precoding matrix is formed by precoding vectors, and the precoding vectors in the precoding matrix may have a same part in terms of composition or other attributes.
  • component vectors forming precoding vectors in a process of constructing the precoding vectors by using a beam combination technology may be the same. Therefore, the foregoing attribute may also be used as an attribute of the precoding matrix, and an indication of the attribute of the precoding matrix is an indication of an attribute of each precoding vector.
  • a specific indication manner may be various existing indication manners, for example but not limited to, the foregoing indication manners and various combinations thereof.
  • the various indication manners refer to the prior art, and details are not described in this specification. It can be learned from the foregoing description that, for example, when a plurality of pieces of information of a same type need to be indicated, different information may be indicated in different manners.
  • a required indication manner may be selected based on a specific requirement. The selected indication manner is not limited in this embodiment of this application. In this way, the indication manner in this embodiment of this application should be understood as covering various methods by using which a to-be-indicated party can learn of to-be-indicated information.
  • the to-be-indicated information may have another equivalent form.
  • a row vector may be expressed as a column vector
  • a matrix may be represented by using a transposed matrix of the matrix
  • a Kronecker product of two vectors may be represented in a form of a product of a vector and a transposed vector of another vector, and the like.
  • the technical solution provided in this embodiment of this application should be understood as covering various forms.
  • some or all of the features in this embodiment of this application should be understood as covering various expression forms of the features.
  • a space-frequency component matrix should be understood as covering various expression forms that can represent the space-frequency matrix.
  • the various expression forms are, for example but not limited to, a Kronecker product of a space-domain component vector and a frequency-domain component vector, a product of one of a space-domain component vector and a frequency-domain component vector and a conjugate transpose vector of the other one of the space-domain component vector and the frequency-domain component vector, an array that includes the foregoing Kronecker product and elements in the product result, and the like.
  • the to-be-indicated information may be sent together as a whole, or may be divided into a plurality of pieces of sub-information and then sent separately.
  • sending periods and/or sending occasions of the pieces of sub-information may be the same or may be different.
  • a specific sending method is not limited in this application.
  • the sending periods and/or sending occasions of the pieces of sub-information may be predefined, for example, predefined according to a protocol, or may be configured by the transmit end device by sending configuration information to the receive end device.
  • the configuration information may include, for example but not limited to, one or a combination of at least two of RRC signaling, MAC signaling, and DCI.
  • the indication information may be a precoding vector indicator (precoding matrix indicator, PMI), or may be other indication information.
  • the indication information may be carried in one or more messages in the prior art and sent by the receive end device to the transmit end device, or may be carried in one or more messages newly designed in this application and sent by the receive end device to the transmit end device.
  • the method shown in FIG. 3 is described based on a case in which a single spatial flow (for example, a data layer obtained through layer mapping) is sent in each subband in a single polarization direction.
  • a person skilled in the art should understand that the technical solution provided in this embodiment of this application is not limited thereto.
  • the technical solution provided in this embodiment of this application may be extended to a case in which a plurality of spatial flows are sent in each subband in a plurality of polarization directions.
  • the indication information includes a related indication of a precoding vector, of each of a plurality of spatial flows, in each of the M subbands, in each of a plurality of polarization directions.
  • the indication information mentioned in this embodiment of this application does not exclude the following case. That is, the indication information indicates the M N-dimensional precoding vectors as described in S101, and further indicates another one or more groups of M N-dimensional precoding vectors. These groups of M N-dimensional precoding vectors may correspond to different polarization directions, different spatial flows, or the like.
  • the indication information includes a related indication of a precoding vector, of each of a plurality of spatial flows, in each of the M subbands, in each of a plurality of polarization directions. It should be understood that a specific indication method may be set based on a specific requirement, for example, by referring to various indication manners described above.
  • a basic space-domain feature and a basic frequency-domain feature are combined to obtain a basic space-frequency feature.
  • the basic space-domain feature may be understood as describing a basic spatial direction
  • the basic frequency-domain feature may be understood as a variation pattern of a channel in a plurality of frequency bands.
  • the space-frequency component matrix can be understood as describing a basic space-frequency feature. Based on this, more space-frequency features can be described by performing weighted summation on a plurality of space-frequency component matrices.
  • S103 The transmit end device receives the indication information.
  • the transmit end device determines the M N dimensional precoding vectors based on the indication information.
  • the M N-dimensional precoding vectors can form a space-frequency matrix and the space-frequency matrix is generated by performing weighted combination on a plurality of space-frequency component matrices, a condition can be created for reducing indication overheads of the precoding vector.
  • the M N-dimensional precoding vectors can be indicated by indicating the space-frequency matrix.
  • the space-frequency matrix may be indicated by indicating the plurality of space-frequency component matrices. Therefore, compared with a technical solution in the prior art in which a precoding vector corresponding to each frequency band is independently indicated, the technical solution provided in this embodiment of this application helps reduce indication overheads.
  • M N-dimensional precoding vectors form an N ⁇ M space-frequency matrix H.
  • Each N-dimensional precoding vector is used as a column vector of the space-frequency matrix H.
  • the space-frequency matrix H is generated by performing weighted combination on a plurality of space-frequency component matrices.
  • Each space-frequency component matrix is a product of a space-domain component vector and a conjugate transpose vector of a frequency-domain component vector.
  • W is a quantity of space-frequency component matrices.
  • u 1 w is a space-domain component vector corresponding to a w th space-frequency component matrix.
  • u 2 w is a frequency-domain component vector corresponding to the w th space-frequency component matrix, and
  • u 2 w ⁇ is a conjugate transpose vector of u 2 w .
  • ⁇ w is a weight of the w th space-frequency component matrix u 1 w u 2 w ⁇
  • u 1 w u 2 w ⁇ is equivalent to h w in Formula 1.
  • M N-dimensional precoding vectors form an M ⁇ N space-frequency matrix H.
  • a conjugate transpose vector of each N-dimensional precoding vector is used as a row vector of the space-frequency matrix H .
  • the space-frequency matrix H is generated by performing weighted combination on a plurality of space-frequency component matrices.
  • Each space-frequency component matrix is a product of a frequency-domain component vector and a conjugate transpose vector of a space-domain component vector.
  • space-domain component vectors corresponding to different space-frequency component matrices may be the same or may be different.
  • Frequency-domain component vectors corresponding to different space-frequency component matrices may be the same or may be different.
  • the space-domain component vector is selected from a space-domain component vector set, or is generated by performing weighted combination on a plurality of space-domain base vectors selected from a space-domain base vector set.
  • quantities of space-domain base vectors corresponding to different space-domain component vectors may be the same or may be different.
  • Different space-domain component vectors may correspond to a same group of space-domain base vectors, or may correspond to different groups of space-domain base vectors.
  • quantities of space-domain base vectors corresponding to different space-frequency component matrices may be the same or may be different.
  • Different space-frequency component matrices may correspond to a same group of space-domain base vectors, or may correspond to different groups of space-domain base vectors.
  • any one or more pieces of information such as: a manner selected for implementing the space-domain component vector (that is, whether the space-domain component vector is selected from the space-domain component vector set or is generated by performing weighted combination on the plurality of space-domain base vectors), whether quantities of space-domain base vectors corresponding to different space-frequency component matrices are the same, a quantity of space-frequency base vectors corresponding to each space-frequency component matrix, and whether space-domain base vectors corresponding to different space-frequency component matrices are a same group of space-domain base vectors, may be predefined, for example, predefined according to a protocol, or may be configured by the transmit end device for the receive end device.
  • the transmit end device may configure any one or more of the foregoing information for the receive end device by using at least one of RRC signaling, MAC signaling, and DCI.
  • the frequency-domain component vector is selected from a frequency-domain component vector set, or is generated by performing weighted combination on a plurality of frequency-domain base vectors selected from a frequency-domain base vector set.
  • quantities of frequency-domain base vectors corresponding to different frequency-domain component vectors may be the same or may be different.
  • Different frequency-domain component vectors may correspond to a same group of frequency-domain base vectors, or may correspond to different groups of frequency-domain base vectors.
  • quantities of frequency-domain base vectors corresponding to different space-frequency component matrices may be the same or may be different.
  • Different space-frequency component matrices may correspond to a same group of frequency-domain base vectors, or may correspond to different groups of frequency-domain base vectors.
  • any one or more pieces of information such as: a manner selected for implementing the frequency-domain component vector (that is, whether the frequency-domain component vector is selected from the frequency-domain component vector set or is generated by performing weighted combination on the plurality of frequency-domain base vectors), whether quantities of frequency-domain base vectors corresponding to different space-frequency component matrices are the same, a quantity of frequency-domain base vectors corresponding to each space-frequency component matrix, and whether frequency-domain base vectors corresponding to different space-frequency component matrices are a same group of frequency-domain base vectors, may be predefined, for example, predefined according to a protocol; or may be configured by the transmit end device for the receive end device.
  • the transmit end device may configure any one or more of the foregoing information for the receive end device by using at least one of RRC signaling, MAC signaling, and DCI.
  • the space-domain component vector is generated by performing weighted combination on the plurality of space-domain base vectors selected from the space-domain base vector set
  • the frequency-domain component vector is generated by performing weighted combination on the plurality of frequency-domain base vectors selected from the frequency-domain base vector set.
  • the receive end device may determine the space-domain base vector and the frequency-domain base vector corresponding to the space-frequency matrix in, for example but not limited to, the following manners:
  • the ideal spatial-frequency matrix H ' may be multiplied by a conjugate transpose matrix of a matrix B1 at the left, and multiplied by a matrix B2 at the right, to obtain a matrix C.
  • B1 is a matrix formed by some or all space-domain base vectors in the space-domain base vector set. Each column of the matrix is a space-domain base vector.
  • B2 is a matrix formed by some or all frequency-domain base vectors in the frequency-domain base vector set. Each column of the matrix is a frequency-domain base vector.
  • W elements in the matrix C are obtained, for example, first W elements that are arranged in descending order of modulus or amplitudes of all elements in the matrix C.
  • a w th element in the W elements may be used as ⁇ w . It may be understood that each element in the matrix C corresponds to one space-domain base vector and one frequency-domain base vector, a space-domain base vector corresponding to the w th element in the W elements may be used as u 1 w , and a frequency-domain base vector corresponding to the w th element may be used as the foregoing u 2 w .
  • the above-described technical solution of first determining the precoded channel matrix corresponding to the M frequency bands and then determining the space-frequency matrix H is used as an example, and the weight of the w th space-frequency component matrix in the combination corresponding to the space-frequency matrix H may be used as ⁇ w .
  • the space-domain base vector corresponding to the w th space-frequency component matrix is used as u 1w
  • the frequency-domain base vector corresponding to the w th space-frequency component matrix is used as u 2 w .
  • a manner of generating a space-frequency component matrix is designed in this application. Specifically, a plurality of space-frequency component matrices share a same group of space-domain component vectors and a same group of frequency-domain component vectors. In this case:
  • u 1, k is a k th space-domain component vector corresponding to the space-frequency matrix H .
  • u 2 l is the first frequency-domain component vector corresponding to the space-frequency matrix H.
  • u 2 l ⁇ is a conjugate transpose vector of u 2
  • l . ⁇ k l is a weight of the (k, l) th space-frequency component matrix.
  • the (k, l) th space-frequency component matrix is a matrix obtained by multiplying u 1, k by u 2 , l ⁇ . 1 ⁇ k ⁇ K, and 1 ⁇ l ⁇ L.
  • K is a quantity of space-domain component vectors corresponding to a space-frequency matrix H
  • L is a quantity of frequency-domain component vectors corresponding to the space-frequency matrix H
  • k, K, l, and L are integers.
  • the (k, l) th space-frequency component matrix is a matrix obtained by multiplying u 2, l by u 1 , k ⁇ .
  • K ⁇ N, and L ⁇ M are based on the formula 4 or the formula 5. If K ⁇ N and/or L ⁇ M, because related information of a precoding vector corresponding to each frequency band is independently indicated in the prior art, related information for constructing an N ⁇ M (or M ⁇ N) matrix needs to be indicated. However, in this optional implementation, only related information for constructing a K ⁇ L (or L ⁇ K) matrix needs to be indicated. Therefore, indication overheads can be reduced.
  • I k is a quantity of space-domain base vectors corresponding to the space-domain component vector u 1, k selected from the space-domain base vector set, and b 1, k , i is an i th space-domain base vector in the I k space-domain base vectors. 1 ⁇ i ⁇ I k , I k ⁇ 2, and both i and I k are integers.
  • c 1, k , i is a weight of b 1, k , i .
  • I is a quantity of space-domain base vectors selected from the space-domain base vector set.
  • the receive end device may not need to indicate, to the transmit end device, a quantity of space-domain base vectors corresponding to each space-domain component vector, but may specifically indicate the quantity I of space-domain base vectors.
  • the receive end device may not need to indicate, to the transmit end device, a space-domain base vector corresponding to each space-frequency component matrix, but may specifically indicate the group of space-domain base vectors.
  • J l is a quantity of frequency-domain base vectors corresponding to the frequency-domain component vector u 2, l selected from the frequency-domain base vector set, and f 2, l , j is a j th frequency-domain base vector in the J l frequency-domain base vectors. 1 ⁇ j ⁇ J l , J l ⁇ 2, and both j and J l are integers.
  • c 2, l , j is a weight of f 2, l , j .
  • J is a quantity of frequency-domain base vectors selected from the frequency-domain base vector set.
  • the receive end device may not need to indicate, to the transmit end device, a quantity of frequency-domain base vectors corresponding to each frequency-domain component vector, but may specifically indicate the quantity J of frequency-domain base vectors.
  • the receive end device may not need to indicate, to the transmit end device, a frequency-domain base vector corresponding to each space-frequency component matrix, but may specifically indicate the group of frequency-domain base vectors.
  • a space-domain base vector corresponding to the elements of the k th row and the l th column in the elements of the K rows and L columns may be used as u 1, k
  • a frequency-domain base vector corresponding to the elements of the k th row and the l th column may be used as u 2, l .
  • the formula 4 may be expressed as the following formula 10 or 11, and the formula 5 may be expressed as the following formula 12 or 13:
  • the weight information may include weights of the plurality of spatial base vectors, weights of the plurality of frequency-domain base vectors, and a weight of the space-frequency component matrix.
  • the indication information may be specifically used to indicate the following information: b 1, k , i , f 2, l,j , c 1 ,k,i , c 2 ,l,j , and ⁇ k,l .
  • the weight information includes weights obtained by multiplying weights of the plurality of spatial base vectors by a weight of the space-frequency component matrix, and weights of the plurality of frequency-domain base vectors.
  • the indication information may be specifically used to indicate the following information: b 1, k , i , f 2 ,l,j , ⁇ k,l c 1 ,k,i and c 2 ,l,j .
  • the weight information may include weights obtained by multiplying weights of the plurality of frequency-domain base vectors by a weight of the space-frequency component matrix, and weights of the plurality of spatial base vectors.
  • the indication information may be specifically used to indicate the following information: b 1, k , i , f 2, l,j , ⁇ k,l c 2 ,l,j and c 1 ,k,i .
  • the transmit end device may approximate the ideal space-frequency matrix to any one of the formulas (including any one of the formulas 2 to formula 13), and therefore, related information in the formula is indicated to the receive end device by using the indication information.
  • the receive end device may obtain the space-frequency matrix based on the formula.
  • the space-frequency matrix may be obtained in another manner.
  • M N-dimensional precoding vectors form an N ⁇ M space-frequency matrix H.
  • Each N-dimensional precoding vector is used as a column vector of the space-frequency matrix H .
  • the space-frequency matrix H is generated by performing weighted combination on a plurality of space-frequency component matrices.
  • Each space-frequency component matrix is selected from a space-frequency component matrix set, or is generated by performing weighted combination on a plurality of space-frequency base matrix sets selected from a space-frequency base matrix.
  • the space-frequency base matrix is an N ⁇ M matrix.
  • Each space-frequency base vector or each space-frequency component matrix in the space-frequency component matrix set may be a product of a space-domain base vector and a conjugate transpose vector of a frequency-domain base vector.
  • M N-dimensional precoding vectors form an M ⁇ N space-frequency matrix H.
  • Each N-dimensional precoding vector is used as a row vector of a space-frequency matrix H.
  • the space-frequency matrix H is generated by performing weighted combination on a plurality of space-frequency component matrices.
  • Each space-frequency component matrix is selected from a space-frequency component matrix set, or is generated by performing weighted combination on a plurality of space-frequency base matrix sets selected from a space-frequency base matrix.
  • the space-frequency base matrix is an M ⁇ N matrix.
  • Each space-frequency base vector or each space-frequency component matrix in the space-frequency component matrix set may be a product of a space-domain base vector and a conjugate transpose vector of a frequency-domain base vector.
  • the receive end device may determine the space-frequency base matrix corresponding to the space-frequency matrix in, for example but not limited to, the following manner:
  • the ideal space-frequency matrix H' may be expanded column by column, to obtain a column vector, and each space-frequency base matrix is expanded column by column, to obtain a column vector; then, an inner product of the column vector obtained by expanding, column by column, each space-frequency base matrix in some or all space-frequency base matrices in the space-frequency base matrix set and the column vector obtained by expanding the ideal space-frequency matrix H' column by column is calculated, to obtain a plurality of inner products; W inner products of the plurality inner products, for example, first W inner products obtained after the plurality of inner products are arranged in descending order, are obtained; and space-frequency base matrices corresponding to the W inner products are used as W space-frequency base matrices corresponding to the space-frequency matrix H .
  • the above-described technical solution of first determining the precoded channel matrix corresponding to the M frequency bands and then determining the space-frequency matrix H is used as an example, and the weight of the w th space-frequency component matrix in the combination corresponding to the space-frequency matrix H may be used as the ⁇ w .
  • the space-frequency base matrix corresponding to the w th space-frequency component matrix is used as h w .
  • the indication information is specifically used to indicate: a plurality of space-frequency component matrices and a weight of each of the plurality of space-frequency component matrices.
  • the indication information may be specifically used to indicate: the plurality of space-frequency component matrices, a plurality of space-frequency base matrices corresponding to each of the plurality of space-frequency component matrices, and weight information.
  • the weight information may include: weights of the plurality of space-frequency base matrices and a weight of the space-frequency component matrix.
  • the weight information includes weights obtained by multiplying weights of the plurality of space-frequency base matrices by a weight of the space-frequency component matrix.
  • FIG. 4 is a schematic flowchart of another channel estimation method according to an embodiment of this application.
  • the method shown in FIG. 4 may include the following steps.
  • a receive end device generates indication information, where the indication information is used to indicate M N-dimensional precoding vectors, each precoding vector is applied to one of M frequency bands, and the M N-dimensional precoding vectors form one M ⁇ N-dimensional space-frequency vector.
  • the space-frequency vector is generated by performing weighted combination on a plurality of space-frequency component vectors, where M ⁇ 1, N ⁇ 2, and M and N are integers.
  • the M ⁇ N-dimensional space-frequency vector may be equivalent to an M ⁇ N-dimensional row vector obtained by expanding the N ⁇ M space-frequency matrix row by row; may be equivalent to an M ⁇ N-dimensional column vector obtained by expanding the N ⁇ M space-frequency matrix column by column; Alternatively, the M ⁇ N-dimensional space-frequency vector may be equivalent to an M ⁇ N-dimensional column vector obtained by expanding the M ⁇ N space-frequency matrix column by column. Alternatively, the M ⁇ N-dimensional space-frequency vector may be equivalent to an M ⁇ N-dimensional row vector obtained by expanding the M ⁇ N space-frequency matrix row by row. Hence, this application is not limited thereto.
  • Z is a quantity of space-frequency component vectors.
  • v z is a z th space-frequency component vector.
  • ⁇ z is a weight of v z .
  • S202 The receive end device sends the indication information.
  • S203 A transmit end device receives the indication information.
  • the transmit end device determines the M N-dimensional precoding vectors based on the indication information.
  • each space-frequency component vector is a Kronecker product of a spatial component vector and a frequency-domain component vector.
  • Z is a quantity of space-frequency component vectors.
  • u 1 z is a spatial component vector corresponding to a z th space-frequency component vector.
  • u 2 z is a frequency-domain component vector corresponding to the z th space-frequency component vector, ⁇ z is a weight of the z th space-frequency component vector, and the z th space-frequency component vector is a Kronecker product of u 1 z and u 2 z .
  • u 1 z ⁇ u 2 z is equivalent to v z in the formula 14.
  • each space-frequency component vector is a Kronecker product of a frequency-domain component vector and a spatial component vector.
  • a z th space-frequency component vector is a Kronecker product of u 2 z and u 1 z .
  • u 2 z ⁇ u 1 z is equivalent to v z in the formula 14.
  • spatial component vectors corresponding to different space-frequency component vectors may be the same or may be different.
  • Frequency-domain component vectors corresponding to different space-frequency component vectors may be the same or may be different.
  • a manner of generating a space-frequency component vector is designed in this application. Specifically, a plurality of space-frequency component vectors share a same group of spatial component vectors and a same group of frequency-domain component vectors. In this case:
  • u 1 c is a c th space-domain component vector corresponding to the space-frequency vector V.
  • u 2 d is a d th frequency-domain component vector corresponding to the space-frequency vector V .
  • ⁇ c,d is a weight of the (c, d) th space-frequency component vector.
  • the (c, d) th space-frequency component vector is a Kronecker product of u 1, c and u 2, d . 1 ⁇ c ⁇ C, and 1 ⁇ d ⁇ D.
  • C is a quantity of space-domain component vectors corresponding to the space-frequency vector V
  • D is a quantity of frequency-domain component vectors corresponding to the space-frequency vector V
  • c, C, d, and D are all integers. In this implementation, there are C ⁇ D space-frequency component vectors.
  • the (c, d) th space-frequency component vector is a Kronecker product of u 2, d and u 1, c .
  • C ⁇ N, and D ⁇ M are based on the formula 17 or 18, C ⁇ N, and D ⁇ M. If C ⁇ N and/or D ⁇ M, because related information of a precoding vector corresponding to each frequency band is independently indicated in the prior art, related information for constructing an N ⁇ M (or M ⁇ N) matrix needs to be indicated. However, in this optional implementation, related information for constructing only a C ⁇ D-dimensional vector needs to be indicated. Therefore, indication overheads can be reduced.
  • the following describes a specific implementation of the indication information when implementations of the spatial component vector and the frequency-domain component vector are different.
  • each space-frequency component vector is selected from a space-frequency component vector set, or is generated by performing weighted combination on a plurality of space-frequency base vector selected from a space-frequency base vector set.
  • a space-frequency base vector may be a Kronecker product of a space-domain base vector and a frequency-domain base vector.
  • a space-frequency base vector may be a Kronecker product of a frequency-domain base vector and a spatial base vector.
  • the indication information may be specifically used to indicate: the plurality of space-frequency component vectors and a weight of each of the plurality of space-frequency component vectors.
  • the indication information may be specifically used to indicate: a plurality of space-frequency base vectors corresponding to each of the plurality of space-frequency component vectors, and weight information.
  • the weight information may include: weights of the plurality of space-frequency base vectors and a weight of the space-frequency component vector.
  • the weight information includes weights obtained by multiplying weights of the plurality of space-frequency base vectors by a weight of the space-frequency component vector.
  • Embodiment 5 or Embodiment 6 for how the receive end device determines the space-domain base vector and the frequency-domain base vector, or in any implementation of Embodiment 7, for how the receive end device determines the space-frequency base vector, refer to the corresponding technical solutions in Embodiment 1 to Embodiment 4, and details are not described herein.
  • the indication information may include at least two pieces of sub-information. Each piece of sub-information may be used to indicate one or more pieces of information indicated by the indication information.
  • sub-information used to indicate a space-domain base vector may be an index of the space-domain base vector (or the frequency-domain base vector, the space-frequency base matrix, the space-frequency base vector, the space-domain component vector, the frequency-domain component vector, the space-frequency component matrix, or the space-frequency component vector).
  • the index of the space-domain base vector may be a number of the space-domain base vector, for example, k or c.
  • indication information used to indicate a plurality of weights of a same type may be the plurality of weights of the same type, or indexes of the plurality of weights of the same type.
  • the receive end device may obtain a weight after normalizing the plurality of weights.
  • the indication information may be further used to indicate a matrix/vector corresponding to a weight used as a normalized reference. In this case, the indication information may not carry the weight used as the normalized reference.
  • the weight of the same type may be a weight of a space-domain base vector, a weight of a frequency-domain base vector, a weight of a space-frequency base matrix, a weight of a space-frequency base vector, a weight of a space-frequency component matrix, a weight of a space-frequency component vector, or a weight of a new type that is obtained by multiplying weights of any two types together.
  • the indication information may be used to indicate a space-frequency component matrix used as a normalized reference. For example, a number of a space-domain base vector and a weight of a frequency-domain base vector that correspond to a space-frequency component matrix may be used to indicate the space-frequency component matrix.
  • weights of different types may be selected from a same group of candidate weights, or may be selected from different groups of candidate weights. This is not limited in this application.
  • the candidate weight may be predefined by both the receive end device and the transmit end device, for example, predefined according to a protocol.
  • sending periods of different sub-information may be the same, or may be different.
  • a sending period of sub-information indicating a space-domain base vector (or a space-domain component vector) is denoted as a first period
  • a sending period of sub-information indicating a frequency-domain base vector (or a frequency-domain component vector) is denoted as a second period
  • a sending period of sub-information indicating a weight of a space-frequency component matrix is denoted as a third period
  • the first period may be greater than, less than, or equal to the second period.
  • the third period is greater than or equal to the first period
  • a fourth period is greater than or equal to the second period.
  • the fourth period may be less than or equal to the first period, and the fourth period may be greater than or equal to the third period. It may be understood that, if the fourth period is the same as the third period, in an implementation, even if the space-domain component vector indicated by the transmit end device to the receive end device is generated by performing weighted combination on a plurality of base vectors selected from a space-domain base vector set, the receive end device may indicate a value obtained by multiplying the weight of the space-domain base vector by the weight of the space-frequency component matrix.
  • a sending period of sub-information indicating a weight of the frequency-domain base vector is denoted as a fifth period
  • the fifth period may be less than or equal to the second period.
  • the fifth period may be greater than or equal to the third period, and the fourth period may be greater than, less than, or equal to the fifth period. It may be understood that, if the fifth period is the same as the third period, in an implementation, even if a frequency-domain component vector indicated by the transmit end device to the receive end device is generated by performing weighted combination on a plurality of base vectors selected from a frequency-domain base vector set, the receive end device may make an indication by multiplying the weight of the frequency-domain base vector by the weight of the space-frequency component matrix.
  • a sending period of sub-information indicating a space-frequency base matrix (or a space-frequency component matrix) is denoted as a sixth period
  • a sending period of sub-information indicating a weight of the space-frequency base matrix is denoted as a seventh period
  • the sixth period may be greater than or equal to the seventh period
  • the sixth period is greater than or equal to the third period
  • the seventh period is greater than or equal to the third period.
  • a sending period of sub-information indicating a weight of a space-frequency component vector is denoted as an eighth period
  • the eighth period may be less than or equal to a minimum value of the first period and the second period
  • the fourth period may be less than or equal to the first period
  • the fourth period may be greater than or equal to the eighth period
  • the fifth period may be greater than or equal to the eighth period.
  • the receive end device may indicate a value obtained by multiplying the weight of the space-domain base vector by the weight of the space-frequency component vector.
  • the receive end device may indicate a value obtained by multiplying the weight of the frequency-domain base vector by the weight of the space-frequency component vector.
  • a sending period of sub-information indicating a space-frequency base vector is denoted as a ninth period
  • a sending period of sub-information indicating a weight of the space-frequency base vector is denoted as a tenth period
  • the ninth period may be greater than or equal to the tenth period
  • the ninth period is greater than or equal to the eighth period
  • the tenth period is greater than or equal to the eighth period.
  • Any one of the first period to the tenth period may be configured by the transmit end device for the receive end device through signaling (for example, RRC signaling, MAC signaling, or DCI), or may be predefined, for example, predefined according to a protocol.
  • signaling for example, RRC signaling, MAC signaling, or DCI
  • the indication information when the indication information indicates the weights of the plurality of space-frequency component matrices (or the space-frequency component vectors), the indication information may indicate only non-zero weights. In this case, the indication information may be further used to indicate a space-frequency component matrix (or a space-frequency component vector) corresponding to the non-zero weights. In addition, when the indication information indicates the weights obtained by multiplying the weights of the plurality of space-frequency component matrices (or the space-frequency component vectors) by the weight of the space-domain base vector (or the frequency-domain base vector), the indication information may indicate only non-zero weights obtained through multiplication. In this case, the indication information may be further used to indicate the space-frequency component matrix (or the space-frequency component vector) and/or the space-domain base vector (or the frequency-domain base vector).
  • a single polarization direction and one spatial flow are used as an example for description above.
  • the indication information may be further used to indicate M N-dimensional precoding vectors in one or more other polarization directions.
  • the indication information may be further used to indicate M N-dimensional precoding vectors of one or more other spatial flows.
  • different polarization directions and/or spatial flows may correspond to a same group of space-frequency component matrices (or space-frequency component vectors, space-domain base vectors, frequency-domain base vectors, space-frequency base matrices, or space-frequency base vectors).
  • the receive end device may not need to indicate a group of space-frequency component matrices (or space-frequency component vectors, space-domain base vectors, frequency-domain base vectors, space-frequency base matrices, or space-frequency base vectors) for each polarization direction and/or spatial flow. In this way, indication overheads can be reduced.
  • different polarization directions and/or spatial flows may alternatively correspond to different groups of space-frequency component matrices (or space-domain component vectors, space-domain component vectors, frequency-domain base vectors, space-frequency base matrices, or space-frequency base vectors).
  • the space-frequency matrix is a space-frequency matrix in a broad sense.
  • quantities of frequency-domain component vectors (or space-domain component vectors, space-frequency component matrices, space-frequency component vectors, frequency-domain base vectors, space-domain base vectors, or space-frequency base vectors) corresponding to space-frequency matrices of different spatial flows are the same.
  • a wideband including M frequency bands corresponds to three spatial flows, which are respectively denoted as spatial flows 1, 2, and 3, a value K corresponding to space-frequency matrices of the spatial flows 1, 2, and 3 are all 4.
  • a larger quantity of spatial flows indicates a smaller quantity of frequency-domain component vectors (or spatial component vectors, space-frequency component matrices, space-frequency component vectors, frequency-domain base vectors, spatial base vectors, or space-frequency base vectors) corresponding to a space-frequency matrix.
  • a wideband including M frequency bands corresponds to three spatial flows, which are respectively denoted as spatial flows 1, 2, and 3, a value K corresponding to space-frequency matrices of the spatial flows 1, 2, and 3 are all 4.
  • a wideband including M frequency bands corresponds to four spatial flows, which are respectively denoted as spatial flows 1, 2, 3, and 4, a value K corresponding to the spatial flows 1, 2, 3, and 4 are all 2.
  • a larger number of a spatial flow indicates a smaller quantity of frequency-domain component vectors (or spatial component vectors, space-frequency component matrices, space-frequency component vectors, frequency-domain base vectors, spatial base vectors, or space-frequency base vectors) corresponding to a space-frequency matrix of the spatial flow.
  • a smaller sequence number of a spatial flow indicates better channel quality corresponding to the spatial flow. For example, if a wideband including M frequency bands corresponds to three spatial flows, which are respectively denoted as spatial flows 1, 2, and 3, a value K corresponding to the spatial flow 1 is 6, a value K corresponding to the spatial flow 2 is 4, and a value K corresponding to the spatial flow 3 is 2.
  • a space-domain base vector (or a frequency-domain base vector, a space-frequency base matrix, or a space-frequency base vector) corresponding to a non-first spatial flow is selected from several space-domain base vectors (or frequency-domain base vectors, space-frequency base matrices, or space-frequency base vectors) corresponding to the first spatial flow.
  • an index of the space-domain base vector (or the frequency-domain base vector, the space-frequency base matrix, or the space-frequency base vector) corresponding to the non-first spatial flow may be a relative index of several space-domain base vectors (or frequency-domain base vectors, space-frequency base matrices, or space-frequency base vectors) corresponding to the first spatial flow.
  • the channel estimation apparatus may be divided into functional modules according to the method examples.
  • the functional modules may be obtained through division corresponding to each function, or two or more functions may be integrated into one processing module.
  • the integrated module may be implemented in a form of hardware, or may be implemented in a form of a software functional module. It should be noted that, in this embodiment of this application, module division is used as an example, and is merely a logical function division. In actual implementation, another division manner may be used.
  • FIG. 5 is a schematic structural diagram of a channel estimation apparatus according to an embodiment of this application.
  • the channel estimation apparatus 500 shown in FIG. 5 may be configured to perform the steps performed by the receive end device or the transmit end device in the channel estimation method shown in FIG. 3 , or may be configured to perform the steps performed by the receive end device or the transmit end device in the channel estimation method shown in FIG. 4 .
  • the channel estimation apparatus 500 may include: a processing unit 501 and a transceiver unit 502.
  • the processing unit 501 may be configured to generate indication information, where the indication information is used to indicate M N-dimensional precoding vectors, each precoding vector is applied to one of M frequency bands, the M N-dimensional precoding vectors form an N ⁇ M or M ⁇ N space-frequency matrix, and the space-frequency matrix is generated by performing weighted combination on a plurality of space-frequency component matrices, where M ⁇ 1, N ⁇ 2, and both M and N are integers.
  • the transceiver unit 502 may be configured to send the indication information.
  • the channel estimation apparatus 500 may be specifically the receive end device in FIG. 3 .
  • the processing unit 501 may be configured to perform S101, and the transceiver unit 502 may be configured to perform S102.
  • the processing unit 501 may be configured to generate indication information, where the indication information is used to indicate M N-dimensional precoding vectors, each precoding vector is applied to one of M frequency bands, the M N-dimensional precoding vectors form an M ⁇ N-dimensional space-frequency vector, and the space-frequency vector is generated by performing weighted combination on a plurality of space-frequency component vectors.
  • the channel estimation apparatus 500 may be specifically the receive end device in FIG. 4 .
  • the processing unit 501 may be configured to perform S201, and the transceiver unit 502 may be configured to perform S202.
  • the transceiver unit 502 may be configured to receive indication information, where the indication information is used to indicate M N-dimensional precoding vectors, each precoding vector is applied to one of M frequency bands, the M N-dimensional precoding vectors form an N ⁇ M or M ⁇ N space-frequency matrix, and the space-frequency matrix is generated by performing weighted combination on a plurality of space-frequency component matrices, where M ⁇ 1, N ⁇ 2, and both M and N are integers.
  • the processing unit 501 may be configured to determine the M N-dimensional precoding vectors based on the indication information.
  • the channel estimation apparatus 500 may be specifically the transmit end device in FIG. 3 .
  • the processing unit 501 may be configured to perform S104, and the transceiver unit 502 may be configured to perform S103.
  • the transceiver unit 502 may be configured to receive indication information, where the indication information is used to indicate M N-dimensional precoding vectors, each precoding vector is applied to one of M frequency bands, the M N-dimensional precoding vectors form an M ⁇ N-dimensional space-frequency vector, and the space-frequency vector is generated by performing weighted combination on a plurality of space-frequency component vectors.
  • the processing unit 501 may be configured to determine the M N-dimensional precoding vectors based on the indication information.
  • the channel estimation apparatus 500 may be specifically the transmit end device in FIG. 4 .
  • the processing unit 501 may be configured to perform S204, and the transceiver unit 502 may be configured to perform S203.
  • the processing unit 501 may correspond to the processor 401 or the processor 408 in FIG. 2
  • the transceiver unit 502 may correspond to the communications interface 404 in FIG. 2 .
  • All or some of the foregoing embodiments may be implemented by using software, hardware, firmware, or any combination thereof.
  • a software program is used for implementation, the embodiments may be implemented completely or partially in a form of a computer program product.
  • the computer program product includes one or more computer instructions. When the computer instructions are loaded and executed on a computer, the procedure or functions according to the embodiments of this application are all or partially generated.
  • the computer may be a general-purpose computer, a dedicated computer, a computer network, or other programmable apparatuses.
  • the computer instructions may be stored in a computer-readable storage medium or may be transmitted from a computer-readable storage medium to another computer-readable storage medium.
  • the computer instructions may be transmitted from a website, computer, server, or data center to another website, computer, server, or data center in a wired (for example, a coaxial cable, an optical fiber, or a digital subscriber line (digital subscriber line, DSL)) or wireless (for example, infrared, radio, or microwave) manner.
  • the computer-readable storage medium may be any usable medium accessible by a computer, or a data storage device, such as a server or a data center, integrating one or more usable media.
  • the usable medium may be a magnetic medium (for example, a floppy disk, a hard disk, or a magnetic tape), an optical medium (for example, a DVD), a semiconductor medium (for example, a solid-state drive (solid state disk, SSD)), or the like.
  • a magnetic medium for example, a floppy disk, a hard disk, or a magnetic tape
  • an optical medium for example, a DVD
  • a semiconductor medium for example, a solid-state drive (solid state disk, SSD)

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US20200358490A1 (en) 2020-11-12
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US11929801B2 (en) 2024-03-12

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